from __future__ import print_function, division

from itertools import product

from sympy.core.sympify import (_sympify, sympify, converter,
    SympifyError)
from sympy.core.basic import Basic
from sympy.core.expr import Expr
from sympy.core.singleton import Singleton, S
from sympy.core.evalf import EvalfMixin
from sympy.core.logic import fuzzy_bool
from sympy.core.numbers import Float
from sympy.core.compatibility import (iterable, with_metaclass,
    ordered, range, PY3)
from sympy.core.evaluate import global_evaluate
from sympy.core.function import FunctionClass
from sympy.core.mul import Mul
from sympy.core.relational import Eq, Ne
from sympy.core.symbol import Symbol, Dummy, _uniquely_named_symbol
from sympy.sets.contains import Contains
from sympy.utilities.iterables import sift
from sympy.utilities.misc import func_name, filldedent
from mpmath import mpi, mpf
from sympy.logic.boolalg import And, Or, Not, true, false
from sympy.utilities import subsets
from sympy.multipledispatch import dispatch

class Set(Basic):
    """
    The base class for any kind of set.

    This is not meant to be used directly as a container of items. It does not
    behave like the builtin ``set``; see :class:`FiniteSet` for that.

    Real intervals are represented by the :class:`Interval` class and unions of
    sets by the :class:`Union` class. The empty set is represented by the
    :class:`EmptySet` class and available as a singleton as ``S.EmptySet``.
    """
    is_number = False
    is_iterable = False
    is_interval = False

    is_FiniteSet = False
    is_Interval = False
    is_ProductSet = False
    is_Union = False
    is_Intersection = None
    is_EmptySet = None
    is_UniversalSet = None
    is_Complement = None
    is_ComplexRegion = False

    @staticmethod
    def _infimum_key(expr):
        """
        Return infimum (if possible) else S.Infinity.
        """
        try:
            infimum = expr.inf
            assert infimum.is_comparable
        except (NotImplementedError,
                AttributeError, AssertionError, ValueError):
            infimum = S.Infinity
        return infimum

    def union(self, other):
        """
        Returns the union of 'self' and 'other'.

        Examples
        ========

        As a shortcut it is possible to use the '+' operator:

        >>> from sympy import Interval, FiniteSet
        >>> Interval(0, 1).union(Interval(2, 3))
        Union(Interval(0, 1), Interval(2, 3))
        >>> Interval(0, 1) + Interval(2, 3)
        Union(Interval(0, 1), Interval(2, 3))
        >>> Interval(1, 2, True, True) + FiniteSet(2, 3)
        Union(Interval.Lopen(1, 2), {3})

        Similarly it is possible to use the '-' operator for set differences:

        >>> Interval(0, 2) - Interval(0, 1)
        Interval.Lopen(1, 2)
        >>> Interval(1, 3) - FiniteSet(2)
        Union(Interval.Ropen(1, 2), Interval.Lopen(2, 3))

        """
        return Union(self, other)

    def intersect(self, other):
        """
        Returns the intersection of 'self' and 'other'.

        >>> from sympy import Interval

        >>> Interval(1, 3).intersect(Interval(1, 2))
        Interval(1, 2)

        >>> from sympy import imageset, Lambda, symbols, S
        >>> n, m = symbols('n m')
        >>> a = imageset(Lambda(n, 2*n), S.Integers)
        >>> a.intersect(imageset(Lambda(m, 2*m + 1), S.Integers))
        EmptySet()

        """
        return Intersection(self, other)

    def intersection(self, other):
        """
        Alias for :meth:`intersect()`
        """
        return self.intersect(other)

    def is_disjoint(self, other):
        """
        Returns True if 'self' and 'other' are disjoint

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 2).is_disjoint(Interval(1, 2))
        False
        >>> Interval(0, 2).is_disjoint(Interval(3, 4))
        True

        References
        ==========

        .. [1] https://en.wikipedia.org/wiki/Disjoint_sets
        """
        return self.intersect(other) == S.EmptySet

    def isdisjoint(self, other):
        """
        Alias for :meth:`is_disjoint()`
        """
        return self.is_disjoint(other)

    def complement(self, universe):
        r"""
        The complement of 'self' w.r.t the given universe.

        Examples
        ========

        >>> from sympy import Interval, S
        >>> Interval(0, 1).complement(S.Reals)
        Union(Interval.open(-oo, 0), Interval.open(1, oo))

        >>> Interval(0, 1).complement(S.UniversalSet)
        UniversalSet() \ Interval(0, 1)

        """
        return Complement(universe, self)

    def _complement(self, other):
        # this behaves as other - self
        if isinstance(other, ProductSet):
            # For each set consider it or it's complement
            # We need at least one of the sets to be complemented
            # Consider all 2^n combinations.
            # We can conveniently represent these options easily using a
            # ProductSet

            # XXX: this doesn't work if the dimensions of the sets isn't same.
            # A - B is essentially same as A if B has a different
            # dimensionality than A
            switch_sets = ProductSet(FiniteSet(o, o - s) for s, o in
                                     zip(self.sets, other.sets))
            product_sets = (ProductSet(*set) for set in switch_sets)
            # Union of all combinations but this one
            return Union(p for p in product_sets if p != other)

        elif isinstance(other, Interval):
            if isinstance(self, Interval) or isinstance(self, FiniteSet):
                return Intersection(other, self.complement(S.Reals))

        elif isinstance(other, Union):
            return Union(o - self for o in other.args)

        elif isinstance(other, Complement):
            return Complement(other.args[0], Union(other.args[1], self), evaluate=False)

        elif isinstance(other, EmptySet):
            return S.EmptySet

        elif isinstance(other, FiniteSet):
            from sympy.utilities.iterables import sift

            sifted = sift(other, lambda x: fuzzy_bool(self.contains(x)))
            # ignore those that are contained in self
            return Union(FiniteSet(*(sifted[False])),
                Complement(FiniteSet(*(sifted[None])), self, evaluate=False)
                if sifted[None] else S.EmptySet)

    def symmetric_difference(self, other):
        """
        Returns symmetric difference of `self` and `other`.

        Examples
        ========

        >>> from sympy import Interval, S
        >>> Interval(1, 3).symmetric_difference(S.Reals)
        Union(Interval.open(-oo, 1), Interval.open(3, oo))
        >>> Interval(1, 10).symmetric_difference(S.Reals)
        Union(Interval.open(-oo, 1), Interval.open(10, oo))

        >>> from sympy import S, EmptySet
        >>> S.Reals.symmetric_difference(EmptySet())
        Reals

        References
        ==========
        .. [1] https://en.wikipedia.org/wiki/Symmetric_difference

        """
        return SymmetricDifference(self, other)

    def _symmetric_difference(self, other):
        return Union(Complement(self, other), Complement(other, self))

    @property
    def inf(self):
        """
        The infimum of 'self'

        Examples
        ========

        >>> from sympy import Interval, Union
        >>> Interval(0, 1).inf
        0
        >>> Union(Interval(0, 1), Interval(2, 3)).inf
        0

        """
        return self._inf

    @property
    def _inf(self):
        raise NotImplementedError("(%s)._inf" % self)

    @property
    def sup(self):
        """
        The supremum of 'self'

        Examples
        ========

        >>> from sympy import Interval, Union
        >>> Interval(0, 1).sup
        1
        >>> Union(Interval(0, 1), Interval(2, 3)).sup
        3

        """
        return self._sup

    @property
    def _sup(self):
        raise NotImplementedError("(%s)._sup" % self)

    def contains(self, other):
        """
        Returns True if 'other' is contained in 'self' as an element.

        As a shortcut it is possible to use the 'in' operator:

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1).contains(0.5)
        True
        >>> 0.5 in Interval(0, 1)
        True

        """
        other = sympify(other, strict=True)
        ret = sympify(self._contains(other))
        if ret is None:
            ret = Contains(other, self, evaluate=False)
        return ret

    def _contains(self, other):
        raise NotImplementedError("(%s)._contains(%s)" % (self, other))

    def is_subset(self, other):
        """
        Returns True if 'self' is a subset of 'other'.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 0.5).is_subset(Interval(0, 1))
        True
        >>> Interval(0, 1).is_subset(Interval(0, 1, left_open=True))
        False

        """
        if isinstance(other, Set):
            return self.intersect(other) == self
        else:
            raise ValueError("Unknown argument '%s'" % other)

    def issubset(self, other):
        """
        Alias for :meth:`is_subset()`
        """
        return self.is_subset(other)

    def is_proper_subset(self, other):
        """
        Returns True if 'self' is a proper subset of 'other'.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 0.5).is_proper_subset(Interval(0, 1))
        True
        >>> Interval(0, 1).is_proper_subset(Interval(0, 1))
        False

        """
        if isinstance(other, Set):
            return self != other and self.is_subset(other)
        else:
            raise ValueError("Unknown argument '%s'" % other)

    def is_superset(self, other):
        """
        Returns True if 'self' is a superset of 'other'.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 0.5).is_superset(Interval(0, 1))
        False
        >>> Interval(0, 1).is_superset(Interval(0, 1, left_open=True))
        True

        """
        if isinstance(other, Set):
            return other.is_subset(self)
        else:
            raise ValueError("Unknown argument '%s'" % other)

    def issuperset(self, other):
        """
        Alias for :meth:`is_superset()`
        """
        return self.is_superset(other)

    def is_proper_superset(self, other):
        """
        Returns True if 'self' is a proper superset of 'other'.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1).is_proper_superset(Interval(0, 0.5))
        True
        >>> Interval(0, 1).is_proper_superset(Interval(0, 1))
        False

        """
        if isinstance(other, Set):
            return self != other and self.is_superset(other)
        else:
            raise ValueError("Unknown argument '%s'" % other)

    def _eval_powerset(self):
        raise NotImplementedError('Power set not defined for: %s' % self.func)

    def powerset(self):
        """
        Find the Power set of 'self'.

        Examples
        ========

        >>> from sympy import FiniteSet, EmptySet
        >>> A = EmptySet()
        >>> A.powerset()
        {EmptySet()}
        >>> A = FiniteSet(1, 2)
        >>> a, b, c = FiniteSet(1), FiniteSet(2), FiniteSet(1, 2)
        >>> A.powerset() == FiniteSet(a, b, c, EmptySet())
        True

        References
        ==========

        .. [1] https://en.wikipedia.org/wiki/Power_set

        """
        return self._eval_powerset()

    @property
    def measure(self):
        """
        The (Lebesgue) measure of 'self'

        Examples
        ========

        >>> from sympy import Interval, Union
        >>> Interval(0, 1).measure
        1
        >>> Union(Interval(0, 1), Interval(2, 3)).measure
        2

        """
        return self._measure

    @property
    def boundary(self):
        """
        The boundary or frontier of a set

        A point x is on the boundary of a set S if

        1.  x is in the closure of S.
            I.e. Every neighborhood of x contains a point in S.
        2.  x is not in the interior of S.
            I.e. There does not exist an open set centered on x contained
            entirely within S.

        There are the points on the outer rim of S.  If S is open then these
        points need not actually be contained within S.

        For example, the boundary of an interval is its start and end points.
        This is true regardless of whether or not the interval is open.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1).boundary
        {0, 1}
        >>> Interval(0, 1, True, False).boundary
        {0, 1}
        """
        return self._boundary

    @property
    def is_open(self):
        """
        Property method to check whether a set is open.
        A set is open if and only if it has an empty intersection with its
        boundary.

        Examples
        ========
        >>> from sympy import S
        >>> S.Reals.is_open
        True
        """
        if not Intersection(self, self.boundary):
            return True
        # We can't confidently claim that an intersection exists
        return None

    @property
    def is_closed(self):
        """
        A property method to check whether a set is closed. A set is closed
        if it's complement is an open set.

        Examples
        ========
        >>> from sympy import Interval
        >>> Interval(0, 1).is_closed
        True
        """
        return self.boundary.is_subset(self)

    @property
    def closure(self):
        """
        Property method which returns the closure of a set.
        The closure is defined as the union of the set itself and its
        boundary.

        Examples
        ========
        >>> from sympy import S, Interval
        >>> S.Reals.closure
        Reals
        >>> Interval(0, 1).closure
        Interval(0, 1)
        """
        return self + self.boundary

    @property
    def interior(self):
        """
        Property method which returns the interior of a set.
        The interior of a set S consists all points of S that do not
        belong to the boundary of S.

        Examples
        ========
        >>> from sympy import Interval
        >>> Interval(0, 1).interior
        Interval.open(0, 1)
        >>> Interval(0, 1).boundary.interior
        EmptySet()
        """
        return self - self.boundary

    @property
    def _boundary(self):
        raise NotImplementedError()

    @property
    def _measure(self):
        raise NotImplementedError("(%s)._measure" % self)

    def __add__(self, other):
        return self.union(other)

    def __or__(self, other):
        return self.union(other)

    def __and__(self, other):
        return self.intersect(other)

    def __mul__(self, other):
        return ProductSet(self, other)

    def __xor__(self, other):
        return SymmetricDifference(self, other)

    def __pow__(self, exp):
        if not sympify(exp).is_Integer and exp >= 0:
            raise ValueError("%s: Exponent must be a positive Integer" % exp)
        return ProductSet([self]*exp)

    def __sub__(self, other):
        return Complement(self, other)

    def __contains__(self, other):
        symb = sympify(self.contains(other))
        if not (symb is S.true or symb is S.false):
            raise TypeError('contains did not evaluate to a bool: %r' % symb)
        return bool(symb)


class ProductSet(Set):
    """
    Represents a Cartesian Product of Sets.

    Returns a Cartesian product given several sets as either an iterable
    or individual arguments.

    Can use '*' operator on any sets for convenient shorthand.

    Examples
    ========

    >>> from sympy import Interval, FiniteSet, ProductSet
    >>> I = Interval(0, 5); S = FiniteSet(1, 2, 3)
    >>> ProductSet(I, S)
    Interval(0, 5) x {1, 2, 3}

    >>> (2, 2) in ProductSet(I, S)
    True

    >>> Interval(0, 1) * Interval(0, 1) # The unit square
    Interval(0, 1) x Interval(0, 1)

    >>> coin = FiniteSet('H', 'T')
    >>> set(coin**2)
    {(H, H), (H, T), (T, H), (T, T)}


    Notes
    =====

    - Passes most operations down to the argument sets
    - Flattens Products of ProductSets

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Cartesian_product
    """
    is_ProductSet = True

    def __new__(cls, *sets, **assumptions):
        def flatten(arg):
            if isinstance(arg, Set):
                if arg.is_ProductSet:
                    return sum(map(flatten, arg.args), [])
                else:
                    return [arg]
            elif iterable(arg):
                return sum(map(flatten, arg), [])
            raise TypeError("Input must be Sets or iterables of Sets")
        sets = flatten(list(sets))

        if EmptySet() in sets or len(sets) == 0:
            return EmptySet()

        if len(sets) == 1:
            return sets[0]

        return Basic.__new__(cls, *sets, **assumptions)

    def _eval_Eq(self, other):
        if not other.is_ProductSet:
            return

        if len(self.args) != len(other.args):
            return false

        return And(*(Eq(x, y) for x, y in zip(self.args, other.args)))

    def _contains(self, element):
        """
        'in' operator for ProductSets

        Examples
        ========

        >>> from sympy import Interval
        >>> (2, 3) in Interval(0, 5) * Interval(0, 5)
        True

        >>> (10, 10) in Interval(0, 5) * Interval(0, 5)
        False

        Passes operation on to constituent sets
        """
        try:
            if len(element) != len(self.args):
                return false
        except TypeError:  # maybe element isn't an iterable
            return false
        return And(*
            [set.contains(item) for set, item in zip(self.sets, element)])

    @property
    def sets(self):
        return self.args

    @property
    def _boundary(self):
        return Union(ProductSet(b + b.boundary if i != j else b.boundary
                                for j, b in enumerate(self.sets))
                                for i, a in enumerate(self.sets))


    @property
    def is_iterable(self):
        """
        A property method which tests whether a set is iterable or not.
        Returns True if set is iterable, otherwise returns False.

        Examples
        ========

        >>> from sympy import FiniteSet, Interval, ProductSet
        >>> I = Interval(0, 1)
        >>> A = FiniteSet(1, 2, 3, 4, 5)
        >>> I.is_iterable
        False
        >>> A.is_iterable
        True

        """
        return all(set.is_iterable for set in self.sets)

    def __iter__(self):
        """
        A method which implements is_iterable property method.
        If self.is_iterable returns True (both constituent sets are iterable),
        then return the Cartesian Product. Otherwise, raise TypeError.
        """
        if self.is_iterable:
            return product(*self.sets)
        else:
            raise TypeError("Not all constituent sets are iterable")

    @property
    def _measure(self):
        measure = 1
        for set in self.sets:
            measure *= set.measure
        return measure

    def __len__(self):
        return Mul(*[len(s) for s in self.args])

    def __bool__(self):
        return all([bool(s) for s in self.args])

    __nonzero__ = __bool__


class Interval(Set, EvalfMixin):
    """
    Represents a real interval as a Set.

    Usage:
        Returns an interval with end points "start" and "end".

        For left_open=True (default left_open is False) the interval
        will be open on the left. Similarly, for right_open=True the interval
        will be open on the right.

    Examples
    ========

    >>> from sympy import Symbol, Interval
    >>> Interval(0, 1)
    Interval(0, 1)
    >>> Interval.Ropen(0, 1)
    Interval.Ropen(0, 1)
    >>> Interval.Ropen(0, 1)
    Interval.Ropen(0, 1)
    >>> Interval.Lopen(0, 1)
    Interval.Lopen(0, 1)
    >>> Interval.open(0, 1)
    Interval.open(0, 1)

    >>> a = Symbol('a', real=True)
    >>> Interval(0, a)
    Interval(0, a)

    Notes
    =====
    - Only real end points are supported
    - Interval(a, b) with a > b will return the empty set
    - Use the evalf() method to turn an Interval into an mpmath
      'mpi' interval instance

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Interval_%28mathematics%29
    """
    is_Interval = True

    def __new__(cls, start, end, left_open=False, right_open=False):

        start = _sympify(start)
        end = _sympify(end)
        left_open = _sympify(left_open)
        right_open = _sympify(right_open)

        if not all(isinstance(a, (type(true), type(false)))
            for a in [left_open, right_open]):
            raise NotImplementedError(
                "left_open and right_open can have only true/false values, "
                "got %s and %s" % (left_open, right_open))

        inftys = [S.Infinity, S.NegativeInfinity]
        # Only allow real intervals (use symbols with 'is_real=True').
        if not all(i.is_real is not False or i in inftys for i in (start, end)):
            raise ValueError("Non-real intervals are not supported")

        # evaluate if possible
        if (end < start) == True:
            return S.EmptySet
        elif (end - start).is_negative:
            return S.EmptySet

        if end == start and (left_open or right_open):
            return S.EmptySet
        if end == start and not (left_open or right_open):
            if start == S.Infinity or start == S.NegativeInfinity:
                return S.EmptySet
            return FiniteSet(end)

        # Make sure infinite interval end points are open.
        if start == S.NegativeInfinity:
            left_open = true
        if end == S.Infinity:
            right_open = true

        return Basic.__new__(cls, start, end, left_open, right_open)

    @property
    def start(self):
        """
        The left end point of 'self'.

        This property takes the same value as the 'inf' property.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1).start
        0

        """
        return self._args[0]

    _inf = left = start

    @classmethod
    def open(cls, a, b):
        """Return an interval including neither boundary."""
        return cls(a, b, True, True)

    @classmethod
    def Lopen(cls, a, b):
        """Return an interval not including the left boundary."""
        return cls(a, b, True, False)

    @classmethod
    def Ropen(cls, a, b):
        """Return an interval not including the right boundary."""
        return cls(a, b, False, True)

    @property
    def end(self):
        """
        The right end point of 'self'.

        This property takes the same value as the 'sup' property.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1).end
        1

        """
        return self._args[1]

    _sup = right = end

    @property
    def left_open(self):
        """
        True if 'self' is left-open.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1, left_open=True).left_open
        True
        >>> Interval(0, 1, left_open=False).left_open
        False

        """
        return self._args[2]

    @property
    def right_open(self):
        """
        True if 'self' is right-open.

        Examples
        ========

        >>> from sympy import Interval
        >>> Interval(0, 1, right_open=True).right_open
        True
        >>> Interval(0, 1, right_open=False).right_open
        False

        """
        return self._args[3]

    def _complement(self, other):
        if other == S.Reals:
            a = Interval(S.NegativeInfinity, self.start,
                         True, not self.left_open)
            b = Interval(self.end, S.Infinity, not self.right_open, True)
            return Union(a, b)

        if isinstance(other, FiniteSet):
            nums = [m for m in other.args if m.is_number]
            if nums == []:
                return None

        return Set._complement(self, other)

    @property
    def _boundary(self):
        finite_points = [p for p in (self.start, self.end)
                         if abs(p) != S.Infinity]
        return FiniteSet(*finite_points)

    def _contains(self, other):
        if not isinstance(other, Expr) or (
                other is S.Infinity or
                other is S.NegativeInfinity or
                other is S.NaN or
                other is S.ComplexInfinity) or other.is_real is False:
            return false

        if self.start is S.NegativeInfinity and self.end is S.Infinity:
            if not other.is_real is None:
                return other.is_real

        if self.left_open:
            expr = other > self.start
        else:
            expr = other >= self.start

        if self.right_open:
            expr = And(expr, other < self.end)
        else:
            expr = And(expr, other <= self.end)

        return _sympify(expr)

    @property
    def _measure(self):
        return self.end - self.start

    def to_mpi(self, prec=53):
        return mpi(mpf(self.start._eval_evalf(prec)),
            mpf(self.end._eval_evalf(prec)))

    def _eval_evalf(self, prec):
        return Interval(self.left._eval_evalf(prec),
            self.right._eval_evalf(prec),
                        left_open=self.left_open, right_open=self.right_open)

    def _is_comparable(self, other):
        is_comparable = self.start.is_comparable
        is_comparable &= self.end.is_comparable
        is_comparable &= other.start.is_comparable
        is_comparable &= other.end.is_comparable

        return is_comparable

    @property
    def is_left_unbounded(self):
        """Return ``True`` if the left endpoint is negative infinity. """
        return self.left is S.NegativeInfinity or self.left == Float("-inf")

    @property
    def is_right_unbounded(self):
        """Return ``True`` if the right endpoint is positive infinity. """
        return self.right is S.Infinity or self.right == Float("+inf")

    def as_relational(self, x):
        """Rewrite an interval in terms of inequalities and logic operators."""
        x = sympify(x)
        if self.right_open:
            right = x < self.end
        else:
            right = x <= self.end
        if self.left_open:
            left = self.start < x
        else:
            left = self.start <= x
        return And(left, right)

    def _eval_Eq(self, other):
        if not other.is_Interval:
            if (other.is_Union or other.is_Complement or
                other.is_Intersection or other.is_ProductSet):
                return

            return false

        return And(Eq(self.left, other.left),
                   Eq(self.right, other.right),
                   self.left_open == other.left_open,
                   self.right_open == other.right_open)


class Union(Set, EvalfMixin):
    """
    Represents a union of sets as a :class:`Set`.

    Examples
    ========

    >>> from sympy import Union, Interval
    >>> Union(Interval(1, 2), Interval(3, 4))
    Union(Interval(1, 2), Interval(3, 4))

    The Union constructor will always try to merge overlapping intervals,
    if possible. For example:

    >>> Union(Interval(1, 2), Interval(2, 3))
    Interval(1, 3)

    See Also
    ========

    Intersection

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Union_%28set_theory%29
    """
    is_Union = True

    def __new__(cls, *args, **kwargs):
        evaluate = kwargs.get('evaluate', global_evaluate[0])

        # flatten inputs to merge intersections and iterables
        args = list(args)

        def flatten(arg):
            if isinstance(arg, Set):
                if arg.is_Union:
                    return sum(map(flatten, arg.args), [])
                else:
                    return [arg]
            if iterable(arg):  # and not isinstance(arg, Set) (implicit)
                return sum(map(flatten, arg), [])
            raise TypeError("Input must be Sets or iterables of Sets")
        args = flatten(args)

        # Union of no sets is EmptySet
        if len(args) == 0:
            return S.EmptySet

        # Reduce sets using known rules
        if evaluate:
            return simplify_union(args)

        args = list(ordered(args, Set._infimum_key))

        return Basic.__new__(cls, *args)

    def _complement(self, universe):
        # DeMorgan's Law
        return Intersection(s.complement(universe) for s in self.args)

    @property
    def _inf(self):
        # We use Min so that sup is meaningful in combination with symbolic
        # interval end points.
        from sympy.functions.elementary.miscellaneous import Min
        return Min(*[set.inf for set in self.args])

    @property
    def _sup(self):
        # We use Max so that sup is meaningful in combination with symbolic
        # end points.
        from sympy.functions.elementary.miscellaneous import Max
        return Max(*[set.sup for set in self.args])

    def _contains(self, other):
        return Or(*[set.contains(other) for set in self.args])

    @property
    def _measure(self):
        # Measure of a union is the sum of the measures of the sets minus
        # the sum of their pairwise intersections plus the sum of their
        # triple-wise intersections minus ... etc...

        # Sets is a collection of intersections and a set of elementary
        # sets which made up those intersections (called "sos" for set of sets)
        # An example element might of this list might be:
        #    ( {A,B,C}, A.intersect(B).intersect(C) )

        # Start with just elementary sets (  ({A}, A), ({B}, B), ... )
        # Then get and subtract (  ({A,B}, (A int B), ... ) while non-zero
        sets = [(FiniteSet(s), s) for s in self.args]
        measure = 0
        parity = 1
        while sets:
            # Add up the measure of these sets and add or subtract it to total
            measure += parity * sum(inter.measure for sos, inter in sets)

            # For each intersection in sets, compute the intersection with every
            # other set not already part of the intersection.
            sets = ((sos + FiniteSet(newset), newset.intersect(intersection))
                    for sos, intersection in sets for newset in self.args
                    if newset not in sos)

            # Clear out sets with no measure
            sets = [(sos, inter) for sos, inter in sets if inter.measure != 0]

            # Clear out duplicates
            sos_list = []
            sets_list = []
            for set in sets:
                if set[0] in sos_list:
                    continue
                else:
                    sos_list.append(set[0])
                    sets_list.append(set)
            sets = sets_list

            # Flip Parity - next time subtract/add if we added/subtracted here
            parity *= -1
        return measure

    @property
    def _boundary(self):
        def boundary_of_set(i):
            """ The boundary of set i minus interior of all other sets """
            b = self.args[i].boundary
            for j, a in enumerate(self.args):
                if j != i:
                    b = b - a.interior
            return b
        return Union(map(boundary_of_set, range(len(self.args))))

    def as_relational(self, symbol):
        """Rewrite a Union in terms of equalities and logic operators. """
        if len(self.args) == 2:
            a, b = self.args
            if (a.sup == b.inf and a.inf is S.NegativeInfinity
                    and b.sup is S.Infinity):
                return And(Ne(symbol, a.sup), symbol < b.sup, symbol > a.inf)
        return Or(*[set.as_relational(symbol) for set in self.args])

    @property
    def is_iterable(self):
        return all(arg.is_iterable for arg in self.args)

    def _eval_evalf(self, prec):
        try:
            return Union(set._eval_evalf(prec) for set in self.args)
        except (TypeError, ValueError, NotImplementedError):
            import sys
            raise (TypeError("Not all sets are evalf-able"),
                   None,
                   sys.exc_info()[2])

    def __iter__(self):
        import itertools

        # roundrobin recipe taken from itertools documentation:
        # https://docs.python.org/2/library/itertools.html#recipes
        def roundrobin(*iterables):
            "roundrobin('ABC', 'D', 'EF') --> A D E B F C"
            # Recipe credited to George Sakkis
            pending = len(iterables)
            if PY3:
                nexts = itertools.cycle(iter(it).__next__ for it in iterables)
            else:
                nexts = itertools.cycle(iter(it).next for it in iterables)
            while pending:
                try:
                    for next in nexts:
                        yield next()
                except StopIteration:
                    pending -= 1
                    nexts = itertools.cycle(itertools.islice(nexts, pending))

        if all(set.is_iterable for set in self.args):
            return roundrobin(*(iter(arg) for arg in self.args))
        else:
            raise TypeError("Not all constituent sets are iterable")

class Intersection(Set):
    """
    Represents an intersection of sets as a :class:`Set`.

    Examples
    ========

    >>> from sympy import Intersection, Interval
    >>> Intersection(Interval(1, 3), Interval(2, 4))
    Interval(2, 3)

    We often use the .intersect method

    >>> Interval(1,3).intersect(Interval(2,4))
    Interval(2, 3)

    See Also
    ========

    Union

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Intersection_%28set_theory%29
    """
    is_Intersection = True

    def __new__(cls, *args, **kwargs):
        evaluate = kwargs.get('evaluate', global_evaluate[0])

        # flatten inputs to merge intersections and iterables
        args = list(args)

        def flatten(arg):
            if isinstance(arg, Set):
                if arg.is_Intersection:
                    return sum(map(flatten, arg.args), [])
                else:
                    return [arg]
            if iterable(arg):  # and not isinstance(arg, Set) (implicit)
                return sum(map(flatten, arg), [])
            raise TypeError("Input must be Sets or iterables of Sets")
        args = flatten(args)

        if len(args) == 0:
            return S.UniversalSet

        # args can't be ordered for Partition see issue #9608
        if 'Partition' not in [type(a).__name__ for a in args]:
            args = list(ordered(args, Set._infimum_key))

        # Reduce sets using known rules
        if evaluate:
            return simplify_intersection(args)

        return Basic.__new__(cls, *args)

    @property
    def is_iterable(self):
        return any(arg.is_iterable for arg in self.args)

    @property
    def _inf(self):
        raise NotImplementedError()

    @property
    def _sup(self):
        raise NotImplementedError()

    def _contains(self, other):
        return And(*[set.contains(other) for set in self.args])

    def __iter__(self):
        no_iter = True
        for s in self.args:
            if s.is_iterable:
                no_iter = False
                other_sets = set(self.args) - set((s,))
                other = Intersection(other_sets, evaluate=False)
                for x in s:
                    c = sympify(other.contains(x))
                    if c is S.true:
                        yield x
                    elif c is S.false:
                        pass
                    else:
                        yield c

        if no_iter:
            raise ValueError("None of the constituent sets are iterable")

    @staticmethod
    def _handle_finite_sets(args):
        from sympy.core.logic import fuzzy_and, fuzzy_bool
        from sympy.core.compatibility import zip_longest

        fs_args, other = sift(args, lambda x: x.is_FiniteSet,
            binary=True)
        if not fs_args:
            return
        s = fs_args[0]
        fs_args = fs_args[1:]

        res = []
        unk = []
        for x in s:
            c = fuzzy_and(fuzzy_bool(o.contains(x))
                for o in fs_args + other)
            if c:
                res.append(x)
            elif c is None:
                unk.append(x)
            else:
                pass  # drop arg
        res = FiniteSet(
            *res, evaluate=False) if res else S.EmptySet
        if unk:
            symbolic_s_list = [x for x in s if x.has(Symbol)]
            non_symbolic_s = s - FiniteSet(
                *symbolic_s_list, evaluate=False)
            while fs_args:
                v = fs_args.pop()
                if all(i == j for i, j in zip_longest(
                        symbolic_s_list,
                        (x for x in v if x.has(Symbol)))):
                    # all the symbolic elements of `v` are the same
                    # as in `s` so remove the non-symbol containing
                    # expressions from `unk`, since they cannot be
                    # contained
                    for x in non_symbolic_s:
                        if x in unk:
                            unk.remove(x)
                else:
                    # if only a subset of elements in `s` are
                    # contained in `v` then remove them from `v`
                    # and add this as a new arg
                    contained = [x for x in symbolic_s_list
                        if sympify(v.contains(x)) is S.true]
                    if contained != symbolic_s_list:
                        other.append(
                            v - FiniteSet(
                            *contained, evaluate=False))
                    else:
                        pass  # for coverage

            other_sets = Intersection(*other)
            if not other_sets:
                return S.EmptySet  # b/c we use evaluate=False below
            res += Intersection(
                FiniteSet(*unk),
                other_sets, evaluate=False)
        return res

    def as_relational(self, symbol):
        """Rewrite an Intersection in terms of equalities and logic operators"""
        return And(*[set.as_relational(symbol) for set in self.args])


class Complement(Set, EvalfMixin):
    r"""Represents the set difference or relative complement of a set with
    another set.

    `A - B = \{x \in A| x \\notin B\}`


    Examples
    ========

    >>> from sympy import Complement, FiniteSet
    >>> Complement(FiniteSet(0, 1, 2), FiniteSet(1))
    {0, 2}

    See Also
    =========

    Intersection, Union

    References
    ==========

    .. [1] http://mathworld.wolfram.com/ComplementSet.html
    """

    is_Complement = True

    def __new__(cls, a, b, evaluate=True):
        if evaluate:
            return Complement.reduce(a, b)

        return Basic.__new__(cls, a, b)

    @staticmethod
    def reduce(A, B):
        """
        Simplify a :class:`Complement`.

        """
        if B == S.UniversalSet or A.is_subset(B):
            return EmptySet()

        if isinstance(B, Union):
            return Intersection(s.complement(A) for s in B.args)

        result = B._complement(A)
        if result is not None:
            return result
        else:
            return Complement(A, B, evaluate=False)

    def _contains(self, other):
        A = self.args[0]
        B = self.args[1]
        return And(A.contains(other), Not(B.contains(other)))


class EmptySet(with_metaclass(Singleton, Set)):
    """
    Represents the empty set. The empty set is available as a singleton
    as S.EmptySet.

    Examples
    ========

    >>> from sympy import S, Interval
    >>> S.EmptySet
    EmptySet()

    >>> Interval(1, 2).intersect(S.EmptySet)
    EmptySet()

    See Also
    ========

    UniversalSet

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Empty_set
    """
    is_EmptySet = True
    is_FiniteSet = True

    @property
    def _measure(self):
        return 0

    def _contains(self, other):
        return false

    def as_relational(self, symbol):
        return false

    def __len__(self):
        return 0

    def __iter__(self):
        return iter([])

    def _eval_powerset(self):
        return FiniteSet(self)

    @property
    def _boundary(self):
        return self

    def _complement(self, other):
        return other

    def _symmetric_difference(self, other):
        return other


class UniversalSet(with_metaclass(Singleton, Set)):
    """
    Represents the set of all things.
    The universal set is available as a singleton as S.UniversalSet

    Examples
    ========

    >>> from sympy import S, Interval
    >>> S.UniversalSet
    UniversalSet()

    >>> Interval(1, 2).intersect(S.UniversalSet)
    Interval(1, 2)

    See Also
    ========

    EmptySet

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Universal_set
    """

    is_UniversalSet = True

    def _complement(self, other):
        return S.EmptySet

    def _symmetric_difference(self, other):
        return other

    @property
    def _measure(self):
        return S.Infinity

    def _contains(self, other):
        return true

    def as_relational(self, symbol):
        return true

    @property
    def _boundary(self):
        return EmptySet()


class FiniteSet(Set, EvalfMixin):
    """
    Represents a finite set of discrete numbers

    Examples
    ========

    >>> from sympy import FiniteSet
    >>> FiniteSet(1, 2, 3, 4)
    {1, 2, 3, 4}
    >>> 3 in FiniteSet(1, 2, 3, 4)
    True

    >>> members = [1, 2, 3, 4]
    >>> f = FiniteSet(*members)
    >>> f
    {1, 2, 3, 4}
    >>> f - FiniteSet(2)
    {1, 3, 4}
    >>> f + FiniteSet(2, 5)
    {1, 2, 3, 4, 5}

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Finite_set
    """
    is_FiniteSet = True
    is_iterable = True

    def __new__(cls, *args, **kwargs):
        evaluate = kwargs.get('evaluate', global_evaluate[0])
        if evaluate:
            args = list(map(sympify, args))

            if len(args) == 0:
                return EmptySet()
        else:
            args = list(map(sympify, args))

        args = list(ordered(frozenset(tuple(args)), Set._infimum_key))
        obj = Basic.__new__(cls, *args)
        obj._elements = frozenset(args)
        return obj

    def _eval_Eq(self, other):
        if not other.is_FiniteSet:
            if (other.is_Union or other.is_Complement or
                other.is_Intersection or other.is_ProductSet):
                return

            return false

        if len(self) != len(other):
            return false

        return And(*(Eq(x, y) for x, y in zip(self.args, other.args)))

    def __iter__(self):
        return iter(self.args)

    def _complement(self, other):
        if isinstance(other, Interval):
            nums = sorted(m for m in self.args if m.is_number)
            if other == S.Reals and nums != []:
                syms = [m for m in self.args if m.is_Symbol]
                # Reals cannot contain elements other than numbers and symbols.

                intervals = []  # Build up a list of intervals between the elements
                intervals += [Interval(S.NegativeInfinity, nums[0], True, True)]
                for a, b in zip(nums[:-1], nums[1:]):
                    intervals.append(Interval(a, b, True, True))  # both open
                intervals.append(Interval(nums[-1], S.Infinity, True, True))

                if syms != []:
                    return Complement(Union(intervals, evaluate=False),
                            FiniteSet(*syms), evaluate=False)
                else:
                    return Union(intervals, evaluate=False)
            elif nums == []:
                return None

        elif isinstance(other, FiniteSet):
            unk = []
            for i in self:
                c = sympify(other.contains(i))
                if c is not S.true and c is not S.false:
                    unk.append(i)
            unk = FiniteSet(*unk)
            if unk == self:
                return
            not_true = []
            for i in other:
                c = sympify(self.contains(i))
                if c is not S.true:
                    not_true.append(i)
            return Complement(FiniteSet(*not_true), unk)

        return Set._complement(self, other)

    def _contains(self, other):
        """
        Tests whether an element, other, is in the set.

        Relies on Python's set class. This tests for object equality
        All inputs are sympified

        Examples
        ========

        >>> from sympy import FiniteSet
        >>> 1 in FiniteSet(1, 2)
        True
        >>> 5 in FiniteSet(1, 2)
        False

        """
        r = false
        for e in self._elements:
            # override global evaluation so we can use Eq to do
            # do the evaluation
            t = Eq(e, other, evaluate=True)
            if t is true:
                return t
            elif t is not false:
                r = None
        return r

    @property
    def _boundary(self):
        return self

    @property
    def _inf(self):
        from sympy.functions.elementary.miscellaneous import Min
        return Min(*self)

    @property
    def _sup(self):
        from sympy.functions.elementary.miscellaneous import Max
        return Max(*self)

    @property
    def measure(self):
        return 0

    def __len__(self):
        return len(self.args)

    def as_relational(self, symbol):
        """Rewrite a FiniteSet in terms of equalities and logic operators. """
        from sympy.core.relational import Eq
        return Or(*[Eq(symbol, elem) for elem in self])

    def compare(self, other):
        return (hash(self) - hash(other))

    def _eval_evalf(self, prec):
        return FiniteSet(*[elem._eval_evalf(prec) for elem in self])

    def _hashable_content(self):
        return (self._elements,)

    @property
    def _sorted_args(self):
        return tuple(ordered(self.args, Set._infimum_key))

    def _eval_powerset(self):
        return self.func(*[self.func(*s) for s in subsets(self.args)])

    def __ge__(self, other):
        if not isinstance(other, Set):
            raise TypeError("Invalid comparison of set with %s" % func_name(other))
        return other.is_subset(self)

    def __gt__(self, other):
        if not isinstance(other, Set):
            raise TypeError("Invalid comparison of set with %s" % func_name(other))
        return self.is_proper_superset(other)

    def __le__(self, other):
        if not isinstance(other, Set):
            raise TypeError("Invalid comparison of set with %s" % func_name(other))
        return self.is_subset(other)

    def __lt__(self, other):
        if not isinstance(other, Set):
            raise TypeError("Invalid comparison of set with %s" % func_name(other))
        return self.is_proper_subset(other)


converter[set] = lambda x: FiniteSet(*x)
converter[frozenset] = lambda x: FiniteSet(*x)


class SymmetricDifference(Set):
    """Represents the set of elements which are in either of the
    sets and not in their intersection.

    Examples
    ========

    >>> from sympy import SymmetricDifference, FiniteSet
    >>> SymmetricDifference(FiniteSet(1, 2, 3), FiniteSet(3, 4, 5))
    {1, 2, 4, 5}

    See Also
    ========

    Complement, Union

    References
    ==========

    .. [1] https://en.wikipedia.org/wiki/Symmetric_difference
    """

    is_SymmetricDifference = True

    def __new__(cls, a, b, evaluate=True):
        if evaluate:
            return SymmetricDifference.reduce(a, b)

        return Basic.__new__(cls, a, b)

    @staticmethod
    def reduce(A, B):
        result = B._symmetric_difference(A)
        if result is not None:
            return result
        else:
            return SymmetricDifference(A, B, evaluate=False)


def imageset(*args):
    r"""
    Return an image of the set under transformation ``f``.

    If this function can't compute the image, it returns an
    unevaluated ImageSet object.

    .. math::
        { f(x) | x \in self }

    Examples
    ========

    >>> from sympy import S, Interval, Symbol, imageset, sin, Lambda
    >>> from sympy.abc import x, y

    >>> imageset(x, 2*x, Interval(0, 2))
    Interval(0, 4)

    >>> imageset(lambda x: 2*x, Interval(0, 2))
    Interval(0, 4)

    >>> imageset(Lambda(x, sin(x)), Interval(-2, 1))
    ImageSet(Lambda(x, sin(x)), Interval(-2, 1))

    >>> imageset(sin, Interval(-2, 1))
    ImageSet(Lambda(x, sin(x)), Interval(-2, 1))
    >>> imageset(lambda y: x + y, Interval(-2, 1))
    ImageSet(Lambda(_x, _x + x), Interval(-2, 1))

    Expressions applied to the set of Integers are simplified
    to show as few negatives as possible and linear expressions
    are converted to a canonical form. If this is not desirable
    then the unevaluated ImageSet should be used.

    >>> imageset(x, -2*x + 5, S.Integers)
    ImageSet(Lambda(x, 2*x + 1), Integers)

    See Also
    ========

    sympy.sets.fancysets.ImageSet

    """
    from sympy.core import Lambda
    from sympy.sets.fancysets import ImageSet
    from sympy.sets.setexpr import set_function

    if len(args) < 2:
        raise ValueError('imageset expects at least 2 args, got: %s' % len(args))

    if isinstance(args[0], (Symbol, tuple)) and len(args) > 2:
        f = Lambda(args[0], args[1])
        set_list = args[2:]
    else:
        f = args[0]
        set_list = args[1:]

        if isinstance(f, Lambda):
            pass
        elif (
                isinstance(f, FunctionClass) # like cos
                or func_name(f) == '<lambda>'
                ):
            # TODO: should we support a way to sympify `lambda`?
            if len(set_list) == 1:
                var = _uniquely_named_symbol(Symbol('x'), f(Dummy()))
                expr = f(var)
            else:
                var = [Symbol('x%i' % (i+1)) for i in range(len(set_list))]
                expr = f(*var)
            f = Lambda(var, expr)
        else:
            raise TypeError(filldedent('''
        expecting lambda, Lambda, or FunctionClass, not \'%s\'.''' %
        func_name(f)))

    if any(not isinstance(s, Set) for s in set_list):
        name = [func_name(s) for s in set_list]
        raise ValueError(
            'arguments after mapping should be sets, not %s' % name)

    if len(set_list) == 1:
        set = set_list[0]
        r = set_function(f, set)
        if r is None:
            r = ImageSet(f, set)
        if isinstance(r, ImageSet):
            f, set = r.args

        if f.variables[0] == f.expr:
            return set

        if isinstance(set, ImageSet):
            if len(set.lamda.variables) == 1 and len(f.variables) == 1:
                return imageset(Lambda(set.lamda.variables[0],
                                       f.expr.subs(f.variables[0], set.lamda.expr)),
                                set.base_set)

        if r is not None:
            return r

    return ImageSet(f, *set_list)


def is_function_invertible_in_set(func, setv):
    """
    Checks whether function ``func`` is invertible when the domain is
    restricted to set ``setv``.
    """
    from sympy import exp, log
    # Functions known to always be invertible:
    if func in (exp, log):
        return True
    u = Dummy("u")
    fdiff = func(u).diff(u)
    # monotonous functions:
    # TODO: check subsets (`func` in `setv`)
    if (fdiff > 0) == True or (fdiff < 0) == True:
        return True
    # TODO: support more
    return None


def simplify_union(args):
    """
    Simplify a :class:`Union` using known rules

    We first start with global rules like 'Merge all FiniteSets'

    Then we iterate through all pairs and ask the constituent sets if they
    can simplify themselves with any other constituent.  This process depends
    on ``union_sets(a, b)`` functions.
    """
    from sympy.sets.handlers.union import union_sets

    # ===== Global Rules =====
    # Merge all finite sets
    finite_sets = [x for x in args if x.is_FiniteSet]
    if len(finite_sets) > 1:
        a = (x for set in finite_sets for x in set)
        finite_set = FiniteSet(*a)
        args = [finite_set] + [x for x in args if not x.is_FiniteSet]

    # ===== Pair-wise Rules =====
    # Here we depend on rules built into the constituent sets
    args = set(args)
    new_args = True
    while(new_args):
        for s in args:
            new_args = False
            for t in args - set((s,)):
                new_set = union_sets(s, t)
                # This returns None if s does not know how to intersect
                # with t. Returns the newly intersected set otherwise
                if new_set is not None:
                    if not isinstance(new_set, set):
                        new_set = set((new_set, ))
                    new_args = (args - set((s, t))).union(new_set)
                    break
            if new_args:
                args = new_args
                break

    if len(args) == 1:
        return args.pop()
    else:
        return Union(args, evaluate=False)


def simplify_intersection(args):
    """
    Simplify an intersection using known rules

    We first start with global rules like
    'if any empty sets return empty set' and 'distribute any unions'

    Then we iterate through all pairs and ask the constituent sets if they
    can simplify themselves with any other constituent
    """

    # ===== Global Rules =====
    # If any EmptySets return EmptySet
    if any(s.is_EmptySet for s in args):
        return S.EmptySet

    # Handle Finite sets
    rv = Intersection._handle_finite_sets(args)

    if rv is not None:
        return rv

    # If any of the sets are unions, return a Union of Intersections
    for s in args:
        if s.is_Union:
            other_sets = set(args) - set((s,))
            if len(other_sets) > 0:
                other = Intersection(other_sets)
                return Union(Intersection(arg, other) for arg in s.args)
            else:
                return Union(*[arg for arg in s.args])

    for s in args:
        if s.is_Complement:
            args.remove(s)
            other_sets = args + [s.args[0]]
            return Complement(Intersection(*other_sets), s.args[1])


    from sympy.sets.handlers.intersection import intersection_sets

    # At this stage we are guaranteed not to have any
    # EmptySets, FiniteSets, or Unions in the intersection

    # ===== Pair-wise Rules =====
    # Here we depend on rules built into the constituent sets
    args = set(args)
    new_args = True
    while(new_args):
        for s in args:
            new_args = False
            for t in args - set((s,)):
                new_set = intersection_sets(s, t)
                # This returns None if s does not know how to intersect
                # with t. Returns the newly intersected set otherwise

                if new_set is not None:
                    new_args = (args - set((s, t))).union(set((new_set, )))
                    break
            if new_args:
                args = new_args
                break

    if len(args) == 1:
        return args.pop()
    else:
        return Intersection(args, evaluate=False)


def _handle_finite_sets(op, x, y, commutative):
    # Handle finite sets:
    fs_args, other = sift([x, y], lambda x: isinstance(x, FiniteSet), binary=True)
    if len(fs_args) == 2:
        return FiniteSet(*[op(i, j) for i in fs_args[0] for j in fs_args[1]])
    elif len(fs_args) == 1:
        sets = [_apply_operation(op, other[0], i, commutative) for i in fs_args[0]]
        return Union(*sets)
    else:
        return None

def _apply_operation(op, x, y, commutative):
    from sympy.sets import ImageSet
    from sympy import symbols,Lambda
    d = Dummy('d')

    out = _handle_finite_sets(op, x, y, commutative)
    if out is None:
        out = op(x, y)

    if out is None and commutative:
        out = op(y, x)
    if out is None:
        _x, _y = symbols("x y")
        if isinstance(x, Set) and not isinstance(y, Set):
            out = ImageSet(Lambda(d, op(d, y)), x).doit()
        elif not isinstance(x, Set) and isinstance(y, Set):
            out = ImageSet(Lambda(d, op(x, d)), y).doit()
        else:
            out = ImageSet(Lambda((_x, _y), op(_x, _y)), x, y)
    return out

def set_add(x, y):
    from sympy.sets.handlers.add import _set_add
    return _apply_operation(_set_add, x, y, commutative=True)

def set_sub(x, y):
    from sympy.sets.handlers.add import _set_sub
    return _apply_operation(_set_sub, x, y, commutative=False)

def set_mul(x, y):
    from sympy.sets.handlers.mul import _set_mul
    return _apply_operation(_set_mul, x, y, commutative=True)

def set_div(x, y):
    from sympy.sets.handlers.mul import _set_div
    return _apply_operation(_set_div, x, y, commutative=False)

def set_pow(x, y):
    from sympy.sets.handlers.power import _set_pow
    return _apply_operation(_set_pow, x, y, commutative=False)

def set_function(f, x):
    from sympy.sets.handlers.functions import _set_function
    return _set_function(f, x)
